Mucosal immunity and vaccination.

The gut mucosal immune system is a critical component of the body's defense against pathogenic organisms, especially those responsible for enteric infections associated with diarrhoeal disease. Attempts to vaccinate against infections of mucosal tissues have been less successful than vaccination against systemic infections, to a large extent reflecting a still incomplete knowledge about the most efficient means for inducing protective local immune responses at these sites. Secretory IgA (SIgA) is the predominating immunoglobulin along mucosal surfaces, and SIgA antibodies generated in gastrointestinal, respiratory or genito-urinary mucosal tissues can confer protection against infections affecting or originating in these sites. An efficacious intestinal SIgA immunity-inducing oral vaccine against cholera has been developed recently, and development of oral vaccines against other enteric infections such as those caused by enterotoxigenic Escherichia coli, Shigella and rotaviruses is in progress as well. Based on the concept of a common mucosal immune system through which activated lymphocytes from the gut can disseminate immunity to other mucosal and glandular tissues, there is currently also much interest in the possibility of developing oral vaccines against infections in the respiratory and urogenital tracts. However, the large and repeated antigen doses often required to achieve a protective immune response still makes this vaccination approach impractical for many purified antigens. There is, therefore, a great need to develop strategies for enhancing delivery of antigen to the mucosal immune system as well as to identify mucosa-active immunostimulating agents (adjuvants). These and other aspects of mucosal immunity in relation to immunization and vaccine development are discussed in this short review article.     

Vaccines against enteric infections for the developing world

Since the first licensure of the Sabin oral polio vaccine more than 50 years ago, only eight enteric vaccines have been licensed for four disease indications, and all are given orally. While mucosal vaccines offer programmatically attractive tools for facilitating vaccine deployment, their development remains hampered by several factors:

• — limited knowledge regarding the properties of the gut immune system during early life;
• — lack of mucosal adjuvants, limiting mucosal vaccine development to live-attenuated or killed whole virus and bacterial vaccines;
• — lack of correlates/surrogates of mucosal immune protection; and
• — limited knowledge of the factors contributing to oral vaccine underperformance in children from developing countries.

There are now reasons to believe that the development of safe and effective mucosal adjuvants and of programmatically sound intervention strategies could enhance the efficacy of current and next-generation enteric vaccines, especially in lesser developed countries which are often co-endemic for enteric infections and malnutrition. These vaccines must be safe and affordable for the world''s poorest, confer long-term protection and herd immunity, and must be able to contain epidemics.     

Protective Immunity Induced by Oral Immunization with a Rotavirus DNA Vaccine Encapsulated in Microparticles

DNA vaccines are usually given by intramuscular injection or by gene gun delivery of DNA-coated particles into the epidermis. Induction of mucosal immunity by targeting DNA vaccines to mucosal surfaces may offer advantages, and an oral vaccine could be effective for controlling infections of the gut mucosa. In a murine model, we obtained protective immune responses after oral immunization with a rotavirus VP6 DNA vaccine encapsulated in poly(lactide-coglycolide) (PLG) microparticles. One dose of vaccine given to BALB/c mice elicited both rotavirus-specific serum antibodies and intestinal immunoglobulin A (IgA). After challenge at 12 weeks postimmunization with homologous rotavirus, fecal rotavirus antigen was significantly reduced compared with controls. Earlier and higher fecal rotavirus-specific IgA responses were noted during the peak period of viral shedding, suggesting that protection was due to specific mucosal immune responses. The results that we obtained with PLG-encapsulated rotavirus VP6 DNA are the first to demonstrate protection against an infectious agent elicited after oral administration of a DNA vaccine.     

New knowledge on pathogenesis of bacterial enteric infections as applied to vaccine development.

This review attempts to synthesize the new knowledge of pathogenesis of bacterial enteric infections and relate this information to vaccine development. Discussion focuses on human infections and to those in which significant strides have been made. As a general theme in the pathogenesis of bacterial enteric infections, pathogens can be characterized into 5 groups on the basis of their degree of ultimate invasiveness after ingestion by a susceptible hose: mucosal adherence and enterotoxin production; mucosal adherence and brush border dissolution -- enteropathogenic E. coli (EPEC) of "classical" serotypes; mucosal invasion and intraepithelial cell proliferation; mucosal translocation followed by bacterial proliferation in the lamina propria and mesenteric lymph nodes; and mucosal translocation followed by generalized infection. The review covers cholera (motility and chemotaxis, mucosal adhesion, flagellar sheath protein, hemagglutinins, outer membrane proteins, enterotoxin production, quality and duration of infection derived immunity, immune response in humans, LPS, flagellar sheath protein, cholera lectin, other cholera hemagglutinins, outer membrane protein, previous cholera vaccines, killer whole cell vaccines, toxoids, combination vaccines, attenuated versus cholerae vaccines): enterotoxigenic Escherichia coli (ETEC) (entertoxins, O:H serotypes and enterotoxin phenotypes, colonization factors, immune response in humans, vaccines against ETEC, and toxiods); EPEC (vaccines against EPEC); Shigella (smooth LPS O antigen, epithelial cell invasiveness, Shigella toxin, and Shigella vaccines); and typhoid fever (caccines against typhoid fever). The major attraction of a nonliving oral cholera vaccine is its safety. A review of available information leads to the conclusion that an oral vaccine consisting of a combination of antigens, intending to stimulate both antibacterial and antitoxic immunity, would be most likely to succeed. Current approaches to immunoprophylaxis of ETEC infection involve vaccines that stimulate antitoxic or antiadhesion immunity or both by means of killed antigens or attenuated strains. It is likely that the most effective vaccines will contain appropriate antigens intended to simultaneously stimulate both antibacterial and antitoxic immunity, thereby leading to a synergistic protective effect. Now that the speical enteroadhesive properties of EPEC have been characterized and shown to be associated with a plasmid, it should be possible to identify the phenotypic gene products responsible for this phenomenon. It is likely that fimbriae or outer membrane proteins will prove to be the organelle of adhesion. When such information becomes available, it should be possible to prepare oral vaccines consisting of the purified antigen. Efficacy has been shown for attenuated Shigella strains utilized as oral vaccines. The major thrust in the development of new immunization agensts against typhoid fever is to identify immunizing agents at least equal in efficacy to the parenteral acetone killed vaccine but which cause no adverse reactions.     

人类口服病毒疫苗的研究进展

研制能同时诱导有效黏膜免疫和系统免疫的疫苗是预防黏膜感染病原体的理想目标。消化道具有许多产生黏膜免疫的位点,包括口腔、胃和小肠等。理想的口服病毒疫苗不仅能诱导较好的局部及远端黏膜免疫,也能产生较好的系统免疫,而且还因为具有无痛接种、可自行服用等优势而备受关注。由于人消化道环境及黏膜免疫的复杂性,目前成功上市的人口服病毒疫苗仅限于3种减毒活疫苗。本文将从消化道黏膜免疫的特点、当前口服病毒疫苗种类及研究现状、口服病毒疫苗所面临的挑战等方面进行综述,期望对我国人口服病毒疫苗的研究和开发提供参考和借鉴。     

Systemic and mucosal immunity induced by oral somatic transgene vaccination against glycoprotein B of pseudorabies virus using live attenuated Salmonella typhimurium

Glycoprotein B mediates the absorption and penetration of the pseudorabies virus in the form of an immunodominant Ag, and represents a major target for the development of new vaccines. This study evaluated the efficiency of live attenuated Salmonella typhimurium SL7207 for the oral delivery of DNA vaccine encoding the pseudorabies virus glycoprotein B (pCI-PrVgB) in vivo, leading to the generation of both systemic and mucosal immunity against the pseudorabies virus Ag. An oral transgene vaccination of pCI-PrVgB using a Salmonella carrier produced a broad spectrum of immunity at both the systemic and mucosal sites, whereas the intramuscular administration of a naked DNA vaccine elicited no mucosal immunoglobulin (Ig)A response. Interestingly, the Salmonella-mediated oral transgene vaccination of the pseudorabies virus glycoprotein B biased the immune responses to the Th2-type, as determined by the IgG2a/IgG1 ratio and the cytokine production profile. However, oral vaccination mediated by Salmonella harbouring pCI-PrVgB showed inferior protection to systemic immunization against virulent pseudorabies virus infection. The expression of transgene delivered by Salmonella bacteria in antigen-presenting cells of both the systemic and mucosal-associated lymphoid tissues was further demonstrated. These results highlight the potential use of live attenuated S. typhimurium for an oral transgene pseudorabies virus glycoprotein B vaccination to induce broad immune responses.     

Mucosal immunization using recombinant plant-based oral vaccines

The induction of mucosal immunity is very important in conferring protection against pathogens that typically invade via mucosal surfaces. Delivery of a vaccine to a mucosal surface optimizes the induction of mucosal immunity. The apparent linked nature of the mucosal immune system allows delivery to any mucosal surface to potentially induce immunity at others. Oral administration is a very straightforward and inexpensive approach to deliver a vaccine to the mucosal lining of the gut. However, vaccines administered by this route are subject to proteolysis in the gastrointestinal tract. Thus, dose levels for protein subunit vaccines are likely to be very high and the antigen may need to be protected from proteolysis for oral delivery to be efficacious. Expression of candidate vaccine antigens in edible recombinant plant material offers an inexpensive means to deliver large doses of vaccines in encapsulated forms. Certain plant tissues can also stably store antigens for extensive periods of time at ambient temperatures, obviating the need for a cold-chain during vaccine storage and distribution, and so further limiting costs. Antigens can be expressed from transgenes stably incorporated into a host plant's nuclear or plastid genome, or from engineered plant viruses infected into plant tissues. Molecular approaches can serve to boost expression levels and target the expressed protein for appropriate post-translational modification. There is a wide range of options for processing plant tissues to allow for oral delivery of a palatable product. Alternatively, the expressed antigen can be enriched or purified prior to formulation in a tablet or capsule for oral delivery. Fusions to carrier molecules can stabilize the expressed antigen, aid in antigen enrichment or purification strategies, and facilitate delivery to effector sites in the gastrointestinal tract. Many antigens have been expressed in plants. In a few cases, vaccine candidates have entered into early phase clinical trials, and in the case of farmed animal vaccines into relevant animal trials.     

Genetically engineered Bifidobacterium animalis expressing the Salmonella flagellin gene for the mucosal immunization in a mouse model

BACKGROUND: A critical component of the host defense against enteric infections is the immunological response of the mucosal membrane, a major starting point of infectious disease, such as typhoid fever. The mucosal immune system consists of an integrated network of lymphoid tissues, mucous membrane-associated cells, and effector molecules. In the present study, we developed a recombinant Bifidobacterium animalis (B. animalis) genetically modified with the Salmonella flagellin gene for mucosal immunization as an oral typhoid vaccine. METHODS: We constructed an oral vaccine against Salmonella typhimurium, consisting of recombinant B. animalis containing the flagellin gene of Salmonella. The recombinant B. animalis was administered orally to mice every other day for 6 weeks. Anti-flagellin antibodies in the serum and stools were measured by enzyme-linked immunosorbent assay (ELISA). RESULTS: We detected significantly higher levels of flagellin-specific IgA in the serum and stools of the mice treated with the recombinant B. animalis containing the flagellin gene than was seen in those treated with parental B. animalis. CONCLUSIONS: Our findings suggest that an oral vaccination using recombinant B. animalis genetically modified with the flagellin gene of Salmonella may be effective against Salmonella infections.     

Oral bacillus Calmette-Guérin vaccine against tuberculosis: why not?

The bacillus Calmette-Guérin (BCG) vaccine is the only licensed vaccine for human use against tuberculosis (TB). Although controversy exists about its efficacy, the BCG vaccine is able to protect newborns and children against disseminated forms of TB, but fails to protect adults against active forms of TB. In the last few years, interest in the mucosal delivery route for the vaccine has been increasing owing to its increased capacity to induce protective immune responses both in the mucosal and the systemic immune compartments. Here, we show the importance of this route of vaccination in newly developed vaccines, especially for vaccines against TB.     

Human immunodeficiency virus-1 vaccine design: where do we go now?

Numerous human immunodeficiency virus (HIV)-1 vaccines have been developed over the last three decades, but to date an effective HIV-1 vaccine that can be used for prophylactic or therapeutic purposes in humans has not been identified. The failures and limited successes of HIV-1 vaccines have highlighted the gaps in our knowledge with regard to fundamental immunity against HIV-1 and have provided insights for vaccine strategies that may be implemented for designing more effective HIV-1 vaccines in the future. Recent studies have shown that robust mucosal immunity, high avidity and polyfunctional T cells, and broadly neutralizing antibodies are important factors governing the induction of protective immunity against HIV-1. Furthermore, optimization of vaccine delivery methods for DNA or live viral vector-based vaccines, elucidating the immune responses of individuals who remain resistant to HIV-1 infections and also understanding the core immune responses mediating protection against simian immunodeficiency viruses (SIV) and HIV-1 in animal models following vaccination, are key aspects to be regarded for designing more effective HIV-1 vaccines in the future.     

提高黏膜免疫的方法及研究进展

黏膜是很多病原体入侵机体的重要入口,黏膜疫苗能诱导产生黏膜保护性免疫应答和系统性免疫应答,阻止病原微生物黏附、入侵和繁殖。但多数候选黏膜疫苗的安全性、稳定性、免疫效力及保护作用还无法达到理想的效果,佐剂或载体的使用改善了黏膜疫苗存在的不足,使黏膜疫苗有了广阔的发展前景。文章综述了提高黏膜免疫的方法及研究进展。     

Intranasal immunization with chitosan microparticles enhances LACK-DNA vaccine protection and induces specific long-lasting immunity against visceral leishmaniasis

Development of a protective vaccine against Leishmania depends on antigen formulation and adjuvants that induce specific immunity and long-lasting immune responses. We previously demonstrated that BALB/c mice intranasally vaccinated with a plasmid DNA encoding the p36/LACK leishmanial antigen (LACK-DNA) develop a protective immunity for up to 3 months after vaccination, which was linked with the systemic expression of vaccine mRNA in peripheral organs. In this study, LACK-DNA vaccine was associated with biocompatible chitosan microparticles cross-linked with glyceraldehyde (CMC) to boost the long-lasting immunity against the late Leishmania infantum challenge. Infection at 7 days, 3 or 6 months after vaccination resulted in significantly lower parasite loads when compared with non-vaccinated controls. Besides, LACK-DNA-chitosan vaccinated mice showed long-time protection observed after the late time point challenge. The achieved protection was correlated with an enhanced spleen cell responsiveness to parasite antigens, marked by increased proliferation and IFN-γ as well as decreased IL-10 production. Moreover, we found diminished systemic levels of TNF-α that was compatible with the better health condition observed in LACK-DNA/CMC vaccinated-infected mice. Together, our data indicate the feasibility of chitosan microparticles as a delivery system tool to extend the protective immunity conferred by LACK-DNA vaccine, which may be explored in vaccine formulations against Leishmania parasite infections.     

Endocine?, N3OA and N3OASq; Three Mucosal Adjuvants That Enhance the Immune Response to Nasal Influenza Vaccination

Annual outbreaks of seasonal influenza are controlled or prevented through vaccination in many countries. The seasonal vaccines used are either inactivated, currently administered parenterally, or live-attenuated given intranasally. In this study three mucosal adjuvants were examined for the influence on the humoral (mucosal and systemic) and cellular influenza A-specific immune responses induced by a nasally administered vaccine. We investigated in detail how the anionic Endocine™ and the cationic adjuvants N3OA and N3OASq mixed with a split inactivated influenza vaccine induced influenza A-specific immune responses as compared to the vaccine alone after intranasal immunization. The study showed that nasal administration of a split virus vaccine together with Endocine™ or N3OA induced significantly higher humoral and cell-mediated immune responses than the non-adjuvanted vaccine. N3OASq only significantly increased the cell-mediated immune response. Furthermore, nasal administration of the influenza vaccine in combination with any of the adjuvants; Endocine™, N3OA or N3OASq, significantly enhanced the mucosal immunity against influenza HA protein. Thus the addition of these mucosal adjuvants leads to enhanced immunity in the most relevant tissues, the upper respiratory tract and the systemic circulation. Nasal influenza vaccination with an inactivated split vaccine can therefore provide an important mucosal immune response, which is often low or absent after traditional parenteral vaccination.     

Salivary IgA enhancement strategy for development of a nasal-spray anti-caries mucosal vaccine

Dental caries remains one of the most common global chronic diseases caused by Streptococcus mutans,which is prevalent all over the world.The caries prevalence of children aged between 5-6 years old in China is still in very high rate.A potent and effective anti-caries vaccine has long been expected for caries prevention but no vaccines have been brought to market till now mainly due to the low ability to induce and maintain protective antibody in oral fluids.This review will give a brief historical retrospect on study of dental caries and pathogenesis,effective targets for anti-caries vaccines,oral immune system and immunization against dental caries.Then,salivary IgA antibodies and the protective responses are discussed in the context of the ontogeny of mucosal immunity to indigenous oral streptococcal.The methods and advancement for induction of specific anticaries salivary sIgA antibodies and enhancement of specific anti-caries salivary sIgA antibodies by intranasal immunization with a safe effective mucosal adjuvant are described.The progress in the enhancement of salivary sIgA antibodies and anticaries protection by intranasal immunization with flagellin-PAc fusion protein will be highlighted.Finally,some of the main strategies that have been used for successful mucosal vaccination of caries vaccine are reviewed,followed by discussion of the mucosal adjuvant choice for achieving protective immunity at oral mucosal membranes for development of a nasal-spray or nasal-drop anti-caries vaccine for human.     

Dendritic cell‐targeting DNA‐based nasal adjuvants for protective mucosal immunity to Streptococcus pneumoniae

To develop safe vaccines for inducing mucosal immunity to major pulmonary bacterial infections, appropriate vaccine antigens (Ags), delivery systems and nontoxic molecular adjuvants must be considered. Such vaccine constructs can induce Ag‐specific immune responses that protect against mucosal infections. In particular, it has been shown that simply mixing the adjuvant with the bacterial Ag is a relatively easy means of constructing adjuvant‐based mucosal vaccine preparations; the resulting vaccines can elicit protective immunity. DNA‐based nasal adjuvants targeting mucosal DCs have been studied in order to induce Ag‐specific mucosal and systemic immune responses that provide essential protection against microbial pathogens that invade mucosal surfaces. In this review, initially a plasmid encoding the cDNA of Flt3 ligand (pFL), a molecule that is a growth factor for DCs, as an effective adjuvant for mucosal immunity to pneumococcal infections, is introduced. Next, the potential of adding unmethylated CpG oligodeoxynucleotide and pFL together with a pneumococcal Ag to induce protection from pneumococcal infections is discussed. Pneumococcal surface protein A has been used as vaccine for restoring mucosal immunity in older persons. Further, our nasal pFL adjuvant system with phosphorylcholine‐keyhole limpet hemocyanin (PC‐KLH) has also been used in pneumococcal vaccine development to induce complete protection from nasal carriage by Streptococcus pneumoniae . Finally, the possibility that anti‐PC antibodies induced by nasal delivery of pFL plus PC‐KLH may play a protective role in prevention of atherogenesis and thus block subsequent development of cardiovascular disease is discussed.

     

Modulation of immune responses following antigen administration by mucosal route

Most microbial infections are either restricted to the mucosal membranes or the etiologic agents needed to transit the mucosa. Thus, it is desirable to stimulate a mucosal response following vaccination, to block both infection and disease development. Attenuated vaccine carriers mimic natural infections, triggering also mucosal responses. Similar results can be achieved by administering antigens with appropriate adjuvants. However, the delivery of antigens per se is not sufficient to engender a protective response. A successful immunization requires the elicitation of an appropriate type of immune response (e.g. antibodies vs. cell-mediated immunity, Th1 vs. Th2 helper pattern). Therefore, a successful vaccination strategy demands the choice of adequate antigens, and their appropriate delivery and/or formulation to promote the required quality of immune response. Different strategies to optimize the immune responses elicited following vaccine administration by the mucosal route are discussed.     

Improved uptake of plant-derived LTB-linked proteins in carp gut and induction of specific humoral immune responses upon infeed delivery

Oral vaccination of fish is an effortless and stress free immunisation method which can be used for almost any age. However, vaccination via the mucosal route does have disadvantages. For example, the vaccine may induce tolerance and has to be protected to escape digestion. Also the vaccine should be efficiently delivered to immune-competent cells in the gut or other lymphoid organs. In addition, it should be cost effective. Here we present a novel fish vaccination model using potato tubers as vaccine production and delivery system. The model vaccines discussed here include fusion proteins consisting of a gut adhesion molecule (LTB) and a viral peptide or green fluorescent protein (GFP) expressed in potato tubers. The adhesion molecule mediates binding to and uptake from the gut, whereas the viral peptide or GFP functions as model vaccine antigen provoking the induction of an immune response. We demonstrate that fusion to LTB facilitates an elevated uptake of the model vaccines in carp gut mucosa. The plant-derived fusion proteins also elicit a specific systemic humoral immune response upon oral application of crude tuber material incorporated into a standard dietary feed pellet. The data presented here show the promising potentials of the plant as a production system for oral vaccines in aquaculture and feed mediated immunisation of fish.     

Do we need nasal vaccines against COVID 19 to suppress the transmission of infections?

Covid-19 vaccines have within the first year prevented about 14 million deaths but did not induce a strong mucosal immune response. Data from US, UK, Singapore and Israel showed a variable and mostly modest effects of vaccination on virus excretion during breakthrough infections. Contact studies showed decreased transmission of infection from vaccinated index cases, but the effect varied according to dominant virus type, with study type and the nature of the contact group and diminished with time after vaccination. Some researchers suspect that it is unlikely to stop the pandemic with injected vaccines alone. Promising animal experiments were conducted with mucosal vaccines. Mice nasally immunized with a chimpanzee adenovirus vector mounted a mucosal immune response, were protected against viral challenge after a single vaccine dose and suppressed nasal replication of the challenge virus. Phage T4 expressing SARS-CoV-2 spike and nucleocapsid induced a sterilizing lung immunity in nasally vaccinated mice. Also hamsters intranasally immunized with the prefusion-stabilized spike protein showed no infectious virus in nasal turbinates upon challenge. Other studies showed that intranasal vaccination with an adenovirus vaccine reduced but did not eliminated viral transmission from infected to naïve hamsters. Intranasal vaccination of rhesus macaques with adenovirus vaccines also substantially reduced or even suppressed viral replication in the upper and lower respiratory tract. Human data on mucosal SARS-CoV-2 vaccines are so far limited to safety and immunogenicity studies. Aerosolized adenovirus vaccines given either as a booster or as primary immunization were safe and induced similar or superior immune response than injected vaccines while an aerosolized influenza vectored vaccine induced only a weak humoral and cellular immune response. Overall 100 mucosal SARS-CoV-2 vaccines are in development and 20 are in clinical trials. First human trials demonstrate that this will not be an easy task.     

Host responses from innate to adaptive immunity after vaccination: Molecular and cellular events

The availability of effective vaccines has had the most profound positive effect on improving the quality of public health by preventing infectious diseases. Despite many successful vaccines, there are still old and new emerging pathogens against which there is no vaccine available. A better understanding of how vaccines work for providing protection will help to improve current vaccines as well as to develop effective vaccines against pathogens for which we do not have a proper means to control. Recent studies have focused on innate immunity as the first line of host defense and its role in inducing adaptive immunity; such studies have been an intense area of research, which will reveal the immunological mechanisms how vaccines work for protection. Toll-like receptors (TLRs), a family of receptors for pathogen-associated molecular patterns on cells of the innate immune system, play a critical role in detecting and responding to microbial infections. Importantly, the innate immune system modulates the quantity and quality of longterm T and B cell memory and protective immune responses to pathogens. Limited studies suggest that vaccines which mimic natural infection and/or the structure of pathogens seem to be effective in inducing long-term protective immunity. A better understanding of the similarities and differences of the molecular and cellular events in host responses to vaccination and pathogen infection would enable the rationale for design of novel preventive measures against many challenging pathogens.     

轮状病毒灭活疫苗和减毒活疫苗序贯免疫的体液免疫应答效果

目的:评价采用轮状病毒灭活疫苗进行初始免疫,减毒活疫苗进行加强免疫的序贯免疫方案的体液免疫应答效果。方法:将实验小鼠随机分为4组(口服疫苗组、序贯疫苗组、口服对照组及序贯对照组),按相应方案免疫后,ELISA检测血清轮状病毒特异性IgG和IgA、肠道轮状病毒特异性IgA;微量中和实验检测血清病毒特异性中和抗体;同时采用ELISA分析口服活疫苗后病毒排出情况。结果:与对照组相比,序贯疫苗组小鼠产生的轮状病毒特异性血清IgG、IgA、中和抗体及肠道IgA水平显著升高。与口服疫苗组相比,序贯疫苗组的免疫方案诱发的轮状病毒特异性血清IgG、IgA、中和抗体水平显著升高,肠道IgA水平两组间没有显著差异。同时,与口服疫苗组相比,序贯疫苗组中轮状病毒灭活疫苗进行的初始免疫未影响第一次口服活疫苗后病毒的排出量和排出时间,但序贯疫苗组第二次口服活疫苗后病毒的排出量迅速减少,排毒时间快速缩短,与口服疫苗组第三次服苗后病毒的排出量和排出时间相似。结论: 轮状病毒灭活疫苗和减毒活疫苗序贯免疫可有效诱发小鼠全身和黏膜局部的体液免疫应答,该方案将有可能成为轮状病毒疫苗临床应用的候选方案。